Abstract
PC-1 and PC-2 form a heteromeric ion channel complex (hereafter called the Polycystin complex) that is abundantly expressed on primary cilia of renal epithelial cells. Mutations within the polycystin complex cause Autosomal Dominant Polycystic Kidney Disease (ADPKD). The Polycystin complex forms a non-selective cation channel, yet the spatial and temporal regulation of the polycystin complex within the ciliary membrane remains poorly understood, partially due to technical limitations posed by the tiny ciliary compartment. Here, we employ our novel assays to functionally reconstitute the polycystin complex in the plasma membrane. Using whole-cell and ciliary patch-clamp recordings we identified a ciliary enriched oxysterol, 7β,27-DHC, as a critical component required for activation of the polycystin complex. We identified a novel oxysterol binding pocket in PC-2 using molecular docking simulation. We also identified two amino acids within the PC-2 oxysterol binding pocket, E208 and R581, to be critical for 7β,27-DHC dependent polycystin activation in both the plasma membrane and ciliary compartment. Further, we can show that the pharmacological and genetic inhibition of oxysterol synthesis by carbenoxolone (CNX) reduces channel activity in primary cilia. Our findings identified a unique second messenger that regulates the polycystin complex. We hypothesize that cilia-enriched lipids license the polycystin complex to be functional only in the ciliary organelle, thus providing novel insights into the spatial regulation of the polycystin complex. Our results also establish a framework to target the same allosteric regulatory site in the polycystin complex to identify activators of the polycystin channels as novel therapeutic strategies for ADPKD.
Competing Interest Statement
The authors have declared no competing interest.